JP7257194B2 - Control device - Google Patents

Description

TECHNICAL FIELD The present invention relates to a control device, and more particularly to a device for detecting an abnormality in a control system.

As a background art of this technology, there is Japanese Patent Application Laid-Open No. 2015-76024 (Patent Document 1). In this document, "the setpoint, manipulated variable, and control variable are measured when the setpoint of the plant is changed, the measured signals are fitted to define the base function of the reference model, and the control response is adjusted to the base function. Estimate the response of the control variable and the manipulated variable when the set value is changed, or the response of the control variable when a disturbance signal is applied, and use these response data to represent the control characteristics. By finding the optimum value of the adjustment parameter using the evaluation function defined based on this index, the reference model according to the required control characteristics is determined and the control gain is optimized.” described (see abstract).

JP 2015-76024 A

However, the aforementioned prior art (Patent Document 1) adjusts the parameters of the reference model (reference model) according to the characteristics of the controlled object, and does not detect the characteristic abnormality of the controlled object.

A representative example of the invention disclosed in the present application is as follows. That is, a calculation unit that calculates a desired output value of the controlled object, and a gain value adjustment unit that calculates the gain value of the PID controller so that the difference between the desired output value and the output value of the controlled object becomes small. and determining whether at least one of the input information to the controlled object, the output information from the controlled object, and the gain value of the PID controller is within a predetermined range, and the calculation according to the determination result a parameter changing unit for permitting a change of a parameter of a unit and changing a parameter value of the computing unit when the permission is granted ; and a determination unit that determines that there is .

According to one aspect of the present invention, it is possible to detect whether a controlled object is normal or abnormal, and improve the reliability and accuracy of the system. Problems, configurations, and effects other than those described above will be clarified by the following description of the embodiments.

1 is a diagram showing the overall configuration of a control device in Examples 1 to 6; FIG. 1 is a system configuration diagram of a control device in Examples 1 to 6; FIG. 1 is a diagram showing a control device and controlled objects in Examples 1 to 3; FIG. FIG. 10 is a diagram showing processing of a PID controller gain value adjustment unit in Examples 1 to 3; FIG. 10 is a diagram showing processing of a parameter changing unit in Examples 1 to 3; FIG. 10 is a diagram showing processing of a parameter changing unit in Examples 1 to 3; FIG. 10 is a diagram showing processing of a parameter changing unit in Examples 1 to 6; FIG. 10 is a diagram showing processing of a parameter changing unit in Examples 1, 2, 4 to 6; FIG. 10 is a diagram showing processing of a desired output value calculation unit in Embodiment 1; FIG. 10 is a diagram showing processing of a controlled object abnormality determination unit in Examples 1, 2, and 4 to 6; FIG. 10 is a diagram showing processing of a desired output value calculator in Examples 2 and 4 to 6; FIG. 13 is a diagram showing processing of a parameter changing unit in Example 3; FIG. 10 is a diagram showing processing of a desired output value calculation unit in Example 3; FIG. 10 is a diagram showing processing of a controlled object abnormality determination unit in Examples 1, 2, and 4 to 6; FIG. 10 is a diagram showing a control device and a controlled object in Example 4; FIG. 14 is a diagram showing processing of a PID controller gain value adjusting unit in Example 4; FIG. 13 is a diagram showing processing of a parameter changing unit in Example 4; FIG. 13 is a diagram showing processing of a parameter changing unit in Example 4; FIG. 13 is a diagram showing processing of a desired output value calculation unit in Example 4; FIG. 10 is a diagram showing a control device and a controlled object in Example 5; FIG. 14 is a diagram showing processing of a PID controller gain value adjusting unit in Example 5; FIG. 21 is a diagram showing processing of a parameter changing unit in Example 5; FIG. 21 is a diagram showing processing of a parameter changing unit in Example 5; FIG. 13 is a diagram showing processing of a desired output value calculation unit in Example 5; FIG. 12 is a diagram showing a control device and a controlled object in Example 6; FIG. 14 is a diagram showing processing of a PID controller gain value adjusting unit in Example 6; FIG. 20 is a diagram illustrating processing of a parameter changing unit in Example 6; FIG. 20 is a diagram illustrating processing of a parameter changing unit in Example 6; FIG. 14 is a diagram showing processing of a desired output value calculation unit in Example 6;

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

[Example 1]
In the present embodiment, a desired output value calculator for calculating a desired output value of the controlled object, and a calculation unit for calculating the desired output value (time-series signal, etc.) and the output value (time-series signal, etc.) of the controlled object. A PID controller gain value adjustment unit that adjusts the gain value of the PID controller so that the difference becomes small, input information to the controlled object, output information from the controlled object, and gain value of the PID controller a parameter changing unit for changing the parameter value of the desired output value calculating unit based on at least one; and determining whether the controlled object is normal based on the parameter value of the desired output value calculating unit. A control device including a controlled object abnormality determination unit that performs the control is shown.

Also, the desired output value calculator is represented by a transfer function.

Also, the parameter changing unit changes the dead time of the transfer function.

Further, the controlled object normality determination unit determines that the controlled object is abnormal when the dead time of the transfer function is equal to or greater than a predetermined value.

Moreover, the said control apparatus is an apparatus which controls a plant.

FIG. 1 is a diagram showing the overall configuration of the control device 1. As shown in FIG.

In the control device 1 , the PID controller gain value adjusting section 2 adjusts the gain value of the PID controller 5 . The parameter change unit 6 determines whether at least one of the overshoot amount and the undershoot amount of the output from the controlled object is within a predetermined range, and determines whether the gain value newly calculated by the PID controller gain value adjustment unit 2 is within a predetermined range. or not, whether or not the gain value has reached a predetermined value, and whether or not the input value to the controlled object is within a predetermined range. is permitted to change the parameters of the output value calculation unit 4 of . Further, when the parameter change is permitted, the desired change parameter (parameter value) of the output value calculator 4 is calculated. A desired output value calculator 4 calculates a desired profile of the output of the controlled object based on the control target. The PID controller 5 calculates the manipulated variable for controlling the controlled object. The controlled object abnormality determination unit 3 detects an abnormality of the controlled object based on the changed parameters calculated by the parameter change unit 6 .

FIG. 2 is a system configuration diagram of the control device 1. As shown in FIG.

The control device 1 has a storage device 11, a CPU 12, a ROM 13, a RAM 14, a data bus 15, an input circuit 16, an input/output port 17 and an output circuit 18 as hardware. The input circuit 16 processes signals input from the outside. A signal input from the outside is, for example, a signal from a sensor installed or connected to the control device 1 . A signal input from the outside passes through the input circuit 16 and is sent to the input/output port 17 as an input signal. Each piece of input information sent to the input/output port 17 is stored in the RAM 14 or storage device 11 via the data bus 15 . At least one of the ROM 13 and the storage device 11 stores a program for executing processing described later, and the program is executed by the CPU 12 . At that time, the values stored in at least one of the RAM 14 and the storage device 11 are appropriately used for the calculation. Information (values) out of the operation results is sent to the input/output port 17 via the data bus 15 and sent to the output circuit 18 as an output signal. The output circuit 18 outputs an output signal to the outside. The output signal that is output to the outside is an actuator drive signal or the like for causing the controlled object to move as desired.

Note that part of the processing performed by the CPU 12 by executing the program may be performed by another computing device (for example, hardware such as an FPGA (Field Programmable Gate Array) or an ASIC (Application Specific Integrated Circuit)).

FIG. 3 is a diagram showing the control device 1 and the plant 7 controlled by the control device 1. As shown in FIG.

The PID controller 5 calculates a manipulated variable for controlling the temperature of the plant 7 (for example, a target valve opening for adjusting the steam temperature).

Details of each process will be described below.

<PID controller gain value adjustment unit (Fig. 4)>
The PID controller gain value adjusting section 2 adjusts the gain value of the PID controller 5 . Specifically, as shown in FIG. 4, the post-adjustment PID gain provisional value is determined such that the difference between the profile of the plant temperature Tdeg and the profile of the desired plant temperature De_Tdeg is minimized. The obtained provisional values of the P-gain value, I-gain value and D-gain value of the PID controller 5 are defined as Kp_new, Ki_new and Kd_new, respectively.

The evaluation function for evaluating the difference between the profile of the plant temperature Tdeg and the desired profile of the plant temperature De_Tdeg is, for example, the L2 norm that is J2=||Tdeg−De_Tdeg|| or J1=|Tdeg−De_Tdeg| There is an L1 norm and the like. The PID gain value that minimizes J1 and J2 may be determined by data-driven control such as IFT (Iterative Feedback Tuning) and FRIT (Fictitious Reference Iterative Tuning). return home. There are various methods such as Newton's method, Gauss-Newton's method, etc. for optimization, and there are many references, so they will not be described in detail here.

Note that this adjustment process may be performed either offline or online.

<Parameter change section (Figs. 5 to 8)>
The parameter changing unit 6 determines at least one of whether or not the overshoot amount of the output from the controlled object is within a predetermined range and whether or not the undershoot amount is within a predetermined range. is permitted to change the parameters of the output value calculation unit 4 of . Specifically, the parameter change permission flag fp_ref is calculated by the three determination processes shown in FIGS. The parameters of the calculation unit 4 are calculated. Note that at least one of the three determination processes shown in FIGS. 5 to 7 may be implemented.

For example, the processing shown in FIG. 5 is executed to calculate the parameter change permission flag fp_ref.
- When the following condition a) is established, the parameter change permission flag fp_ref=1 is output. On the other hand, if the condition a) is not satisfied, the parameter change permission flag fp_ref=0 is output.
Condition a)
The overshoot amount of Tdeg is K_Tdeg_O1 or more, or
Undershoot amount of Tdeg is K_Tdeg_U1 or more

Also, the processing shown in FIG. 6 is executed to calculate the parameter change permission flag fp_ref.
- When the following condition a) is established, the parameter change permission flag fp_ref=1 is output. On the other hand, if the condition a) is not satisfied, the parameter change permission flag fp_ref=0 is output.
Condition a)
Tg_VO≧K_Tg_VO_H

It should be noted that it is possible to determine whether or not each of the P, I, and D minutes calculated by the PID controller 5 is within a predetermined range instead of Tg_VO (target valve opening degree), which is the output of the PID controller 5. good. The input to the controlled object may be not only the target valve opening, which is the output of the PID controller 5, but also input information to the controlled object such as the target fuel flow rate, the actual valve opening degree, and the fuel flow rate.

Alternatively, fp_ref may be calculated by executing the processing shown in FIG.
- When the following condition a) is established, the parameter change permission flag fp_ref=1 is output. On the other hand, if the condition a) is not satisfied, the parameter change permission flag fp_ref=0 is output.
Condition a)
Kp_new≧K_Kp_new_H, or
Ki_new≧K_Ki_new_H, or
Kd_new≧K_Kd_new_H

Further, a desired change parameter (parameter value) for the output value calculator 4 is calculated according to the parameter change permission flag fp_ref. In the first embodiment, the parameter b1 of the transfer function is the dead time of the transfer function, and specifically, the process shown in FIG. 8 is executed.
• When fp_ref=1, the desired output value calculator parameter b1 is corrected as follows.
b1=b1+k1_b1
• When fp_ref=0, the desired output value calculator parameter b1 maintains its current value.

<Desired output value calculator (Fig. 9)>
The desired output value calculator 4 calculates a desired profile of the output of the controlled object (for example, the temperature of the plant 7) based on the control target. Specifically, as shown in FIG. 9, the profile of the desired plant temperature De_Tdeg is calculated using, for example, a transfer function for the target plant temperature Tg_Tdeg, which is the control target. Control targets include, for example, step signals and ramp signals.

Also, b1, which is one of the parameters of the transfer function, is variable, and the value calculated by the parameter changer 6 is preferably used. The parameter b1 indicates the dead time of the dead time term of the transfer function, and the larger the value of b1, the slower the responsiveness of the transfer function.

<Controlled object abnormality determination unit (Fig. 10)>
The controlled object abnormality determination unit 3 detects an abnormality of the controlled object based on the changed parameters calculated by the parameter change unit 6 . Specifically, as shown in FIG. 10, when the following conditions are satisfied, the controlled object abnormality flag f_ano_plant=1 is output, and when the following conditions are not satisfied, the controlled object abnormality flag f_ano_plant=0 is output.
Condition b1≧K_b1_H

According to this embodiment, the control device 1 that adjusts the gain value of the PID controller 5 includes the desired output value calculator 4 that calculates a desired output value of the controlled object, and the desired output value (time-series signal etc.) and the output value of the controlled object (such as a time-series signal), a PID controller gain value adjustment unit 2 that adjusts the gain value of the PID controller 5, and an input to the controlled object a parameter changing unit 6 for changing a parameter value of a desired output value calculating unit 4 based on at least one of information, output information from the controlled object, and a gain value of the PID controller 5; and a controlled object abnormality determination unit 3 for determining whether or not the controlled object is normal based on the parameter value of 4. Also, the desired output value calculator 4 is represented by a transfer function. Also, the parameter changing unit 6 changes the dead time of the transfer function. Further, the controlled object abnormality determination unit 3 determines that the controlled object is abnormal when the dead time of the transfer function is equal to or greater than a predetermined value. Also, the control device 1 is a device that controls the plant 7 .

When at least one of overshoot and undershoot of the measured value and estimated output of the controlled object occurs (when not within a predetermined range), the output value of the desired output value calculation unit 4 is theoretically There is a possibility that the output value (profile) cannot be realized. That is, there is a possibility that the output value (profile) cannot be realized by correcting the gain value of the PID controller 5 . In this case, in order to suppress overshoot and undershoot, it is necessary to correct the desired output value (profile) of the controlled object to a theoretically achievable one. When the desired output value calculator 4 is represented by a transfer function, the larger the value corresponding to the dead time of the transfer function, the slower the responsiveness of the transfer function. Therefore, in order to delay the responsiveness of the transfer function until at least one of the amount of overshoot and the amount of undershoot becomes considerably small, the value corresponding to the dead time of the transfer function is increased.

Further, when the input value to the controlled object is not within a predetermined range, or when the input value to the controlled object reaches a predetermined value, the desired output value of the output value calculation unit 4 is , the output value (profile) may be unrealizable. That is, there is a possibility that the input value to the controlled object such as the manipulated variable becomes an unrealizable output value (profile). In this case, in order to optimize the input value to the controlled object, it is necessary to correct the desired output value (profile) of the controlled object so as to be realistically achievable. When the desired output value calculator 4 is represented by a transfer function, the larger the value corresponding to the dead time of the transfer function, the slower the responsiveness of the transfer function. Therefore, the value corresponding to the dead time of the transfer function is increased in order to delay the responsiveness of the transfer function until the gain value is optimized (for example, within a predetermined range).

Further, when the gain value newly calculated in the PID controller gain value adjusting section 2 is not within the predetermined range, or when the newly calculated gain value reaches a predetermined value, the desired output value calculating section 4 may be an output value (profile) that cannot be realized realistically due to the specifications of the control system. That is, there is a possibility that the output value (profile) cannot be realized by correcting the gain value of the PID controller 5 . In this case, in order to optimize the newly calculated gain value, it is necessary to correct the desired output value (profile) of the controlled object so as to be realistically achievable. When the desired output value calculator 4 is represented by a transfer function, the larger the value corresponding to the dead time of the transfer function, the slower the responsiveness of the transfer function. Therefore, the value corresponding to the dead time of the transfer function is increased in order to delay the responsiveness of the transfer function until the gain value is optimized (for example, within a predetermined range).

In the control device 1 that adjusts the gain value of the PID controller 5, the controlled object is adjusted so that the difference between the desired output value (time-series signal, etc.) and the output value of the controlled object (time-series signal, etc.) becomes small Input information to the controlled object, output information from the controlled object, or the gain value of the PID controller 5 is determined based on the characteristics of . Furthermore, based on the input information to the controlled object, the output information from the controlled object, or the gain value of the PID controller 5, the parameter value of the desired output value calculation unit 4 is updated, so that the desired output value calculation unit The parameter value of 4 reflects the characteristics of the controlled object.

Therefore, the characteristics of the controlled object can be detected based on the desired parameter values of the output value calculator 4, and it can be determined whether the characteristics of the controlled object are normal or abnormal by evaluating the parameter values.

As described above, according to the present embodiment, it is possible to automatically adjust the PID gain value so as to obtain desired output characteristics according to changes in the characteristics of the controlled object, and to control whether the controlled object is normal or abnormal. can be detected, the reliability and accuracy of the plant control system can be improved.

[Example 2]
In the present embodiment, a desired output value calculator for calculating a desired output value of the controlled object, and a calculation unit for calculating the desired output value (time-series signal, etc.) and the output value (time-series signal, etc.) of the controlled object. A PID controller gain value adjustment unit that adjusts the gain value of the PID controller so that the difference becomes small, input information to the controlled object, output information from the controlled object, and gain value of the PID controller a parameter changing unit for changing the parameter value of the desired output value calculating unit based on at least one; and determining whether the controlled object is normal based on the parameter value of the desired output value calculating unit. A control device including a controlled object abnormality determination unit that performs the control is shown.

Also, the desired output value calculator is represented by a transfer function.

Also, the parameter changing unit changes the time constant of the transfer function.

Further, the controlled object abnormality determination unit determines that the controlled object is abnormal when the time constant of the transfer function is equal to or greater than a predetermined value.

Moreover, the said control apparatus is an apparatus which controls a plant.

FIG. 1 shows the overall configuration of a control device 1 of embodiment 2, which is the same as that of embodiment 1, and therefore will not be described in detail. FIG. 2 shows the system configuration of the control device 1 of embodiment 2, which is the same as that of embodiment 1, and therefore will not be described in detail. FIG. 3 shows the control device 1 of Embodiment 2 and the plant 7 controlled by the control device 1, which is the same as that of Embodiment 1, and therefore will not be described in detail.

Details of each process will be described below.

<PID controller gain value adjustment unit (Fig. 4)>
The PID controller gain value adjusting section 2 adjusts the gain value of the PID controller 5 . Specifically, since it is the same as the first embodiment shown in FIG. 4, it will not be described in detail.

<Parameter change section (Figs. 5 to 8)>
The parameter changing unit 6 determines at least one of whether or not the overshoot amount of the output from the controlled object is within a predetermined range and whether or not the undershoot amount is within a predetermined range. is permitted to change the parameters of the output value calculation unit 4 of . Specifically, since it is the same as the first embodiment shown in FIGS. 5 to 7, the details are omitted.

Further, if change is permitted, a desired change parameter (parameter value) of the output value calculator 4 is calculated. In Example 2, the parameter b1 of the transfer function is the time constant of the transfer function, and the specific calculation method is the same as in Example 1 shown in FIG.

<Desired Output Value Calculator (FIG. 11)>
The desired output value calculator 4 calculates a desired profile of the output of the controlled object (for example, the temperature of the plant 7) based on the control target. Specifically, as shown in FIG. 11, the profile of the desired plant temperature De_Tdeg is calculated using, for example, a transfer function for the target plant temperature Tg_Tdeg, which is the control target. Control targets include, for example, step signals and ramp signals.

Also, b1, which is one of the parameters of the transfer function, is made variable, and the value calculated by the parameter changer 6 is used. The parameter b1 is one of the coefficients of the denominator polynomial of the transfer function, and the larger the value of b1, the slower the response of the transfer function.

<Controlled object abnormality determination unit (Fig. 10)>
The controlled object abnormality determination unit 3 detects an abnormality of the controlled object based on the changed parameters calculated by the parameter change unit 6 . Specifically, since it is the same as the first embodiment shown in FIG. 10, the details will not be described.

According to this embodiment, the control device 1 that adjusts the gain value of the PID controller 5 includes the desired output value calculator 4 that calculates a desired output value of the controlled object, and the desired output value (time-series signal etc.) and the output value of the controlled object (such as a time-series signal), a PID controller gain value adjustment unit 2 that adjusts the gain value of the PID controller 5, and an input to the controlled object a parameter changing unit 6 for changing a parameter value of a desired output value calculating unit 4 based on at least one of information, output information from the controlled object, and a gain value of the PID controller 5; and a controlled object abnormality determination unit 3 for determining whether or not the controlled object is normal based on the parameter value of 4. Also, the desired output value calculator 4 is represented by a transfer function. Also, the parameter changing unit 6 changes the time constant of the transfer function. Further, the controlled object abnormality determination unit 3 determines that the controlled object is abnormal when the time constant of the transfer function is equal to or greater than a predetermined value. Also, the control device is a device for controlling the plant 7 .

When at least one of overshoot and undershoot of the measured value and estimated output of the controlled object occurs (when not within a predetermined range), the output value of the desired output value calculation unit 4 is theoretically There is a possibility that the output value (profile) cannot be realized. That is, there is a possibility that the output value (profile) cannot be realized by correcting the gain value of the PID controller 5 . In this case, in order to suppress overshoot and undershoot, it is necessary to correct the desired output value (profile) of the controlled object to a theoretically achievable one. When the desired output value calculator 4 is represented by a transfer function, the larger the value corresponding to the time constant in the denominator polynomial of the transfer function, the slower the responsiveness of the transfer function. Therefore, in order to delay the responsiveness of the transfer function until at least one of the amount of overshoot and the amount of undershoot becomes considerably small, the value corresponding to the time constant in the denominator polynomial of the transfer function is increased.

Further, when the input value to the controlled object is not within a predetermined range, or when the input value to the controlled object reaches a predetermined value, the desired output value of the output value calculation unit 4 is , the output value (profile) may be unrealizable. That is, there is a possibility that the input value to the controlled object such as the manipulated variable becomes an unrealizable output value (profile). In this case, in order to optimize the input value to the controlled object, it is necessary to correct the desired output value (profile) of the controlled object so as to be realistically achievable. When the desired output value calculator 4 is represented by a transfer function, the larger the value corresponding to the time constant in the denominator polynomial of the transfer function, the slower the responsiveness of the transfer function. Therefore, the value corresponding to the time constant in the denominator polynomial of the transfer function is increased in order to delay the responsiveness of the transfer function until the gain value is optimized (for example, within a predetermined range).

Further, when the gain value newly calculated in the PID controller gain value adjusting section 2 is not within the predetermined range, or when the newly calculated gain value reaches a predetermined value, the desired output value calculating section 4 may be an output value (profile) that cannot be realized realistically due to the specifications of the control system. That is, there is a possibility that the output value (profile) cannot be realized by correcting the gain value of the PID controller 5 . In this case, in order to optimize the newly calculated gain value, it is necessary to correct the desired output value (profile) of the controlled object so as to be realistically achievable. When the desired output value calculator 4 is represented by a transfer function, the larger the value corresponding to the time constant in the denominator polynomial of the transfer function, the slower the responsiveness of the transfer function. Therefore, the value corresponding to the time constant in the denominator polynomial of the transfer function is increased in order to delay the responsiveness of the transfer function until the gain value is optimized (for example, within a predetermined range).

In the configuration for adjusting the gain value of the PID controller 5 so that the difference between the desired output value (time-series signal, etc.) and the output value of the controlled object (time-series signal, etc.) is small, At least one of the input information to the controlled object, the output information from the controlled object, and the gain value of the PID controller 5 is determined based on the characteristics. Further, based on at least one of the input information to the controlled object, the output information from the controlled object, and the gain value of the PID controller 5, the parameter value of the desired output value calculation unit 4 is updated. The desired parameter value of the output value calculator 4 reflects the characteristics of the controlled object.

Therefore, the characteristics of the controlled object can be detected based on the desired parameter values of the output value calculator 4, and it can be determined whether the characteristics of the controlled object are normal or abnormal by evaluating the parameter values.

As described above, according to the present embodiment, it is possible to automatically adjust the PID gain value so as to obtain desired output characteristics according to changes in the characteristics of the controlled object, and to control whether the controlled object is normal or abnormal. can be detected, the reliability and accuracy of the plant control system can be improved.

[Example 3]
In the present embodiment, a desired output value calculator for calculating a desired output value of the controlled object, and a calculation unit for calculating the desired output value (time-series signal, etc.) and the output value (time-series signal, etc.) of the controlled object. A PID controller gain value adjustment unit that adjusts the gain value of the PID controller so that the difference becomes small, input information to the controlled object, output information from the controlled object, and gain value of the PID controller a parameter changing unit for changing the parameter value of the desired output value calculating unit based on at least one; and determining whether the controlled object is normal based on the parameter value of the desired output value calculating unit. A control device including a controlled object abnormality determination unit that performs the control is shown.

Also, the desired output value calculator is represented by a transfer function.

Also, the parameter changing unit changes the order of the transfer function.

Further, the controlled object abnormality determination unit determines that the controlled object is abnormal when the order of the transfer function is equal to or greater than a predetermined value.

Moreover, the said control apparatus is an apparatus which controls a plant.

FIG. 1 shows the overall configuration of a control device 1 of embodiment 3, which is the same as that of embodiment 1, and therefore will not be described in detail. FIG. 2 shows the system configuration of the control device 1 of embodiment 3, which is the same as that of embodiment 1, and therefore will not be described in detail. FIG. 3 shows the control device 1 of Example 3 and the plant 7 controlled by the control device 1, which is the same as that of Example 1, and therefore will not be described in detail.

Details of each process will be described below.

<PID controller gain value adjustment unit (Fig. 4)>
The PID controller gain value adjusting section 2 adjusts the gain value of the PID controller 5 . Specifically, since it is the same as the first embodiment shown in FIG. 4, it will not be described in detail.

<Parameter changing unit (Figs. 5 to 7, Fig. 12)>
The parameter changing unit 6 determines at least one of whether or not the overshoot amount of the output from the controlled object is within a predetermined range and whether or not the undershoot amount is within a predetermined range. is permitted to change the parameters of the output value calculation unit 4 of . Specifically, since it is the same as the first embodiment shown in FIGS. 5 to 7, the details are omitted.

Further, if change is permitted, a desired change parameter (parameter value) of the output value calculator 4 is calculated. Specifically, the processing shown in FIG. 12 is executed.
When fp_ref=1, the desired output value calculator parameter n (the denominator order of the transfer function) is corrected as follows.
n=n+1
• When fp_ref=0, the desired output value calculator parameter n (the denominator order of the transfer function) maintains its current value.

<Desired output value calculator (Fig. 13)>
The desired output value calculator 4 calculates a desired profile of the output of the controlled object (for example, the temperature of the plant 7) based on the control target. Specifically, as shown in FIG. 13, the profile of the desired plant temperature De_Tdeg is calculated using, for example, a transfer function for the target plant temperature Tg_Tdeg, which is the control target. A control target is, for example, a step signal, a ramp signal, or the like.

Also, the denominator order n of the transfer function, which is one of the parameters of the transfer function, may be variable, and the value calculated by the parameter changer 6 may be used. The parameter n is one of the degrees of the denominator polynomial of the transfer function, and the larger the value of n, the slower the response of the transfer function.

<Controlled object abnormality determination unit (Fig. 14)>
The controlled object abnormality determination unit 3 detects an abnormality of the controlled object based on the changed parameters calculated by the parameter change unit 6 . Specifically, as shown in FIG. 14, when the following conditions are satisfied, the controlled object abnormality flag f_ano_plant=1 is output, and when the following conditions are not satisfied, the controlled object abnormality flag f_ano_plant=0 is output.
Condition n≧K_n_H

In the first to third embodiments, the parameters of the desired output value calculator 4 (transfer function) calculated by the parameter changer 6 and used for abnormality detection by the controlled object abnormality determination unit 3 are the dead time and time constant of the transfer function. , the denominator order, but any combination of two or three of these embodiments may be implemented. By detecting anomalies with a plurality of parameters, anomalies in controlled objects can be detected more accurately.

According to this embodiment, the control device 1 that adjusts the gain value of the PID controller 5 includes the desired output value calculator 4 that calculates a desired output value of the controlled object, and the desired output value (time-series signal etc.) and the output value of the controlled object (such as a time-series signal), a PID controller gain value adjustment unit 2 that adjusts the gain value of the PID controller 5, and an input to the controlled object a parameter changing unit 6 for changing a parameter value of a desired output value calculating unit 4 based on at least one of information, output information from the controlled object, and a gain value of the PID controller 5; and a controlled object abnormality determination unit 3 for determining whether or not the controlled object is normal based on the parameter value of 4. Also, the desired output value calculator 4 is represented by a transfer function. Also, the parameter changing unit 6 changes the order of the transfer function. Further, the controlled object abnormality determination unit 3 determines that the controlled object is abnormal when the order of the transfer function is equal to or greater than a predetermined value. Also, the control device is a device for controlling the plant 7 .

When at least one of overshoot and undershoot of the measured value and estimated output of the controlled object occurs (when not within a predetermined range), the output value of the desired output value calculation unit 4 is theoretically There is a possibility that the output value (profile) cannot be realized. That is, there is a possibility that the output value (profile) cannot be realized by correcting the gain value of the PID controller 5 . In this case, in order to suppress overshoot and undershoot, it is necessary to correct the desired output value (profile) of the controlled object to a theoretically achievable one. When the desired output value calculator 4 is represented by a transfer function, the larger the value corresponding to the degree in the denominator polynomial of the transfer function, the slower the responsiveness of the transfer function. Therefore, in order to delay the responsiveness of the transfer function until at least one of the amount of overshoot and the amount of undershoot becomes considerably small, the value corresponding to the order of the denominator polynomial of the transfer function is increased.

Further, when the input value to the controlled object is not within a predetermined range, or when the input value to the controlled object reaches a predetermined value, the desired output value of the output value calculation unit 4 is , the output value (profile) may be unrealizable. That is, there is a possibility that the input value to the controlled object such as the manipulated variable becomes an unrealizable output value (profile). In this case, in order to optimize the input value to the controlled object, it is necessary to correct the desired output value (profile) of the controlled object so as to be realistically achievable. When the desired output value calculator 4 is represented by a transfer function, the larger the value corresponding to the degree in the denominator polynomial of the transfer function, the slower the responsiveness of the transfer function. Therefore, in order to delay the responsiveness of the transfer function until the gain value is optimized (for example, within a predetermined range), the value corresponding to the degree of the denominator polynomial of the transfer function is increased.

Further, when the gain value newly calculated in the PID controller gain value adjusting section 2 is not within the predetermined range, or when the newly calculated gain value reaches a predetermined value, the desired output value calculating section 4 may be an output value (profile) that cannot be realized realistically due to the specifications of the control system. That is, there is a possibility that the output value (profile) cannot be realized by correcting the gain value of the PID controller 5 . In this case, in order to optimize the newly calculated gain value, it is necessary to correct the desired output value (profile) of the controlled object so as to be realistically achievable. When the desired output value calculator 4 is represented by a transfer function, the larger the value corresponding to the degree in the denominator polynomial of the transfer function, the slower the responsiveness of the transfer function. Therefore, in order to delay the responsiveness of the transfer function until the gain value is optimized (for example, within a predetermined range), the value corresponding to the degree of the denominator polynomial of the transfer function is increased.

In the configuration for adjusting the gain value of the PID controller 5 so that the difference between the desired output value (time-series signal, etc.) and the output value of the controlled object (time-series signal, etc.) is small, the characteristics of the controlled object At least one of the input information to the controlled object, the output information from the controlled object, and the gain value of the PID controller 5 is determined based on. Further, based on at least one of the input information to the controlled object, the output information from the controlled object, and the gain value of the PID controller 5, the parameter value of the desired output value calculation unit 4 is updated. The desired parameter value of the output value calculator 4 reflects the characteristics of the controlled object.

Therefore, the characteristics of the controlled object can be detected based on the desired parameter values of the output value calculator 4, and it can be determined whether the characteristics of the controlled object are normal or abnormal by evaluating the parameter values.

As described above, according to the present embodiment, it is possible to automatically adjust the PID gain value so as to obtain desired output characteristics according to changes in the characteristics of the controlled object, and to control whether the controlled object is normal or abnormal. can be detected, the reliability and accuracy of the plant control system can be improved.

[Example 4]
In the present embodiment, a desired output value calculator for calculating a desired output value of the controlled object, and a calculation unit for calculating the desired output value (time-series signal, etc.) and the output value (time-series signal, etc.) of the controlled object. A PID controller gain value adjustment unit that adjusts the gain value of the PID controller so that the difference becomes small, input information to the controlled object, output information from the controlled object, and gain value of the PID controller a parameter changing unit for changing the parameter value of the desired output value calculating unit based on at least one; and determining whether the controlled object is normal based on the parameter value of the desired output value calculating unit. A control device including a controlled object abnormality determination unit that performs the control is shown.

Also, the desired output value calculator is represented by a transfer function.

Also, the parameter changing unit changes the time constant of the transfer function.

Further, the controlled object abnormality determination unit determines that the controlled object is abnormal when the time constant of the transfer function is equal to or greater than a predetermined value.

Further, the control device is a device for controlling an automatic driving vehicle.

FIG. 1 shows the overall configuration of the control device 1, which is the same as that of the first embodiment, and will not be described in detail. FIG. 2 shows the system configuration of the control device 1, which is the same as that of the first embodiment, and will not be described in detail.

FIG. 15 is a diagram showing the control device 1 and the self-driving vehicle 8 controlled by the control device 1. As shown in FIG. The PID controller 5 calculates a manipulated variable (for example, target speed, target rotational angular velocity) for controlling motion of the self-driving vehicle 8 .

Details of each process will be described below.

<PID controller gain value adjustment unit (Fig. 16)>
The PID controller gain value adjusting section 2 adjusts the gain value of the PID controller 5 . Specifically, as shown in FIG. 16, the post-adjustment PID gain provisional value is determined such that the difference between the velocity VSP profile and the desired velocity De_VSP profile is minimized. The obtained provisional values of the P gain value, I gain value, and D gain value of the PID controller 5 are defined as Kp_new, Ki_new_tmp, and Kd_new, respectively.

The evaluation function for evaluating the difference between the velocity VSP profile and the desired velocity De_VSP profile is, for example, the L2 norm that is J2=||VSP-De_VSP|| or the L1 norm that is J1=|VSP-De_VSP| and so on. The PID gain value that minimizes J1 and J2 may be determined by data-driven control such as IFT (Iterative Feedback Tuning) and FRIT (Fictitious Reference Iterative Tuning). return home. There are various methods such as Newton's method, Gauss-Newton's method, etc. for optimization, and there are many references, so they will not be described in detail here.

Note that this optimization process may be performed either offline or online.

<Parameter changing unit (Figs. 17, 18, 7, 8)>
The parameter changing unit 6 determines at least one of whether or not the overshoot amount of the output from the controlled object is within a predetermined range and whether or not the undershoot amount is within a predetermined range. is permitted to change the parameters of the output value calculation unit 4 of . Specifically, the parameter change permission flag fp_ref is calculated by the three determination processes shown in FIGS. , the parameters of the output value calculator 4 are calculated. Note that at least one of the three determination processes shown in FIGS. 17, 18, and 7 may be implemented.

For example, the processing shown in FIG. 17 is executed to calculate the parameter change permission flag fp_ref.
- When the following condition a) is satisfied, the parameter change permission flag fp_ref=1 is output. On the other hand, if the condition a) is not satisfied, the parameter change permission flag fp_ref=0 is output.
Condition a)
VSP overshoot amount is K_VSP_O1 or more, or
VSP undershoot amount is K_VSP_U1 or more

Also, the processing shown in FIG. 18 is executed to calculate the parameter change permission flag fp_ref.
- When the following condition a) is satisfied, the parameter change permission flag fp_ref=1 is output. On the other hand, if the condition a) is not satisfied, the parameter change permission flag fp_ref=0 is output.
Condition a)
Tg_VSP≧K_Tg_VSP_H

Instead of Tg_VSP (target vehicle speed), which is the output of the PID controller 5, it may be determined whether or not the P minute, I minute, and D minute calculated by the PID controller 5 are within predetermined ranges. The input to the controlled object may be not only the target vehicle speed, which is the output of the PID controller 5, but also input information to the controlled object such as a target fuel amount, a target throttle opening, and a target torque.

Further, fp_ref is calculated by the processing shown in FIG. Specifically, since it is the same as that of the first embodiment, a detailed description thereof will be omitted.

Further, if change is permitted, a desired change parameter (parameter value) of the output value calculator 4 is calculated. Specifically, since it is the same as the first embodiment shown in FIG. 8, a detailed description thereof will be omitted.

<Desired Output Value Calculator (FIG. 19)>
The desired output value calculator 4 calculates a desired profile of the output of the controlled object (for example, the speed of the self-driving vehicle 8) based on the control target. Specifically, as shown in FIG. 19, the profile of the desired speed De_VSP is calculated for the target speed Tg_VSP, which is the control target, using, for example, a transfer function. Control targets include, for example, step signals and ramp signals.

Also, b1, which is one of the parameters of the transfer function, is variable, and the value calculated by the parameter changer 6 is preferably used. The parameter b1 is one of the coefficients of the denominator polynomial of the transfer function, and the larger the value of b1, the slower the response of the transfer function.

<Controlled object abnormality determination unit (Fig. 10)>
The controlled object abnormality determination unit 3 detects an abnormality of the controlled object based on the changed parameters calculated by the parameter change unit 6 . Specifically, since it is the same as the first embodiment shown in FIG. 10, the details will not be described.

According to this embodiment, the control device 1 that adjusts the gain value of the PID controller 5 includes the desired output value calculator 4 that calculates a desired output value of the controlled object, and the desired output value (time-series signal etc.) and the output value of the controlled object (such as a time-series signal), a PID controller gain value adjustment unit 2 that adjusts the gain value of the PID controller 5, and an input to the controlled object a parameter changing unit 6 for changing a parameter value of a desired output value calculating unit 4 based on at least one of information, output information from the controlled object, and a gain value of the PID controller 5; and a controlled object abnormality determination unit 3 for determining whether or not the controlled object is normal based on the parameter value of 4. Also, the desired output value calculator 4 is represented by a transfer function. Also, the parameter changing unit 6 changes the time constant of the transfer function. Further, the controlled object abnormality determination unit 3 determines that the controlled object is abnormal when the time constant of the transfer function is equal to or greater than a predetermined value. Further, the control device is a device that controls the automatic driving vehicle 8 .

When at least one of overshoot and undershoot of the measured value and estimated output of the controlled object occurs (when not within a predetermined range), the output value of the desired output value calculation unit 4 is theoretically There is a possibility that the output value (profile) cannot be realized. That is, there is a possibility that the output value (profile) cannot be realized by correcting the gain value of the PID controller 5 . In this case, in order to suppress overshoot and undershoot, it is necessary to correct the desired output value (profile) of the controlled object to a theoretically achievable one. When the desired output value calculator 4 is represented by a transfer function, the larger the value corresponding to the time constant in the denominator polynomial of the transfer function, the slower the responsiveness of the transfer function. Therefore, in order to delay the responsiveness of the transfer function until at least one of the amount of overshoot and the amount of undershoot becomes considerably small, the value corresponding to the time constant in the denominator polynomial of the transfer function is increased.

Further, when the input value to the controlled object is not within a predetermined range, or when the input value to the controlled object reaches a predetermined value, the desired output value of the output value calculation unit 4 is , the output value (profile) may be unrealizable. That is, there is a possibility that the input value to the controlled object such as the manipulated variable becomes an unrealizable output value (profile). In this case, in order to optimize the input value to the controlled object, it is necessary to correct the desired output value (profile) of the controlled object so as to be realistically achievable. When the desired output value calculator 4 is represented by a transfer function, the larger the value corresponding to the time constant in the denominator polynomial of the transfer function, the slower the responsiveness of the transfer function. Therefore, the value corresponding to the time constant in the denominator polynomial of the transfer function is increased in order to delay the responsiveness of the transfer function until the gain value is optimized (for example, within a predetermined range).

Further, when the gain value newly calculated in the PID controller gain value adjusting section 2 is not within the predetermined range, or when the newly calculated gain value reaches a predetermined value, the desired output value calculating section 4 may be an output value (profile) that cannot be realized realistically due to the specifications of the control system. That is, there is a possibility that the output value (profile) cannot be realized by correcting the gain value of the PID controller 5 . In this case, in order to optimize the newly calculated gain value, it is necessary to correct the desired output value (profile) of the controlled object so as to be realistically achievable. When the desired output value calculator 4 is represented by a transfer function, the larger the value corresponding to the time constant in the denominator polynomial of the transfer function, the slower the responsiveness of the transfer function. Therefore, the value corresponding to the time constant in the denominator polynomial of the transfer function is increased in order to delay the responsiveness of the transfer function until the gain value is optimized (for example, within a predetermined range).

In the configuration for adjusting the gain value of the PID controller 5 so that the difference between the desired output value (time-series signal, etc.) and the output value of the controlled object (time-series signal, etc.) is small, At least one of the input information to the controlled object, the output information from the controlled object, and the gain value of the PID controller 5 is determined based on the characteristics. Further, based on at least one of the input information to the controlled object, the output information from the controlled object, and the gain value of the PID controller 5, the parameter value of the desired output value calculation unit 4 is updated. The desired parameter value of the output value calculator 4 reflects the characteristics of the controlled object.

Therefore, the characteristics of the controlled object can be detected based on the desired parameter values of the output value calculator 4, and it can be determined whether the characteristics of the controlled object are normal or abnormal by evaluating the parameter values.

As described above, according to the present embodiment, it is possible to automatically adjust the PID gain value so as to obtain desired output characteristics according to changes in the characteristics of the controlled object, and to control whether the controlled object is normal or abnormal. can be detected, improving the reliability and accuracy of autonomous vehicle control systems.

[Example 5]
In the present embodiment, a desired output value calculator for calculating a desired output value of the controlled object, and a calculation unit for calculating the desired output value (time-series signal, etc.) and the output value (time-series signal, etc.) of the controlled object. A PID controller gain value adjustment unit that adjusts the gain value of the PID controller so that the difference becomes small, input information to the controlled object, output information from the controlled object, and gain value of the PID controller a parameter changing unit for changing the parameter value of the desired output value calculating unit based on at least one; and determining whether the controlled object is normal based on the parameter value of the desired output value calculating unit. A control device including a controlled object abnormality determination unit 3 is shown.

Also, the desired output value calculator is represented by a transfer function.

Also, the parameter changing unit changes the time constant of the transfer function.

Further, the controlled object abnormality determination unit determines that the controlled object is abnormal when the time constant of the transfer function is equal to or greater than a predetermined value.

Also, the control device is a device for controlling a robot.

FIG. 1 shows the overall configuration of the control device 1, which is the same as that of the first embodiment, and will not be described in detail. FIG. 2 shows the system configuration of the control device 1, which is the same as that of the first embodiment, and will not be described in detail.

FIG. 20 is a diagram showing the control device 1 and the robot 9 controlled by the control device 1. As shown in FIG. The PID controller 5 calculates manipulated variables (for example, angle, speed, torque) for controlling motion of the robot 9 .

Details of each process will be described below.

<PID controller gain value adjustment unit (Fig. 21)>
The PID controller gain value adjusting section 2 adjusts the gain value of the PID controller 5 . Specifically, it is shown in FIG.

The post-adjustment PID gain provisional value is determined such that the difference between the profile of the position POS and the profile of the desired position De_POS is minimized. The obtained provisional values of the P-gain value, I-gain value and D-gain value of the PID controller 5 are defined as Kp_new, Ki_new and Kd_new, respectively.

The evaluation function that evaluates the difference between the profile of the position POS and the profile of the desired position De_POS is, for example, the L2 norm that is J2=||POS-De_POS|| or the L1 norm that is J1=|POS-De_POS| and so on. The PID gain value that minimizes J1 and J2 may be determined by data-driven control such as IFT (Iterative Feedback Tuning) and FRIT (Fictitious Reference Iterative Tuning). return home. There are various methods such as Newton's method, Gauss-Newton's method, etc. for optimization, and there are many references, so they will not be described in detail here.

Note that this optimization process may be performed either offline or online.

<Parameter changing unit (Figs. 22, 23, 7, 8)>
The parameter changing unit 6 determines at least one of whether or not the overshoot amount of the output from the controlled object is within a predetermined range and whether or not the undershoot amount is within a predetermined range. is permitted to change the parameters of the output value calculation unit 4 of . Specifically, the parameter change permission flag fp_ref is calculated by the three determination processes shown in FIGS. The parameters of the output value calculator 4 are calculated. Note that at least one of the three determination processes shown in FIGS. 22, 23, and 7 may be implemented.

For example, the processing shown in FIG. 22 is executed to calculate the parameter change permission flag fp_ref.
- When the following condition a) is satisfied, the parameter change permission flag fp_ref=1 is output. On the other hand, if the condition a) is not satisfied, the parameter change permission flag fp_ref=0 is output.
Condition a)
POS overshoot amount is greater than or equal to K_POS_O1, or
POS undershoot amount is more than K_POS_U1

Also, the processing shown in FIG. 23 is executed to calculate the parameter change permission flag fp_ref.
- When the following condition a) is satisfied, the parameter change permission flag fp_ref=1 is output. On the other hand, if the condition a) is not satisfied, the parameter change permission flag fp_ref=0 is output.
Condition a)
Tg_POS≧K_Tg_POS_H

Instead of Tg_POS (target position), which is the output of the PID controller 5, it may be determined whether or not each of the P, I, and D components calculated by the PID controller 5 is within a predetermined range. The input to the controlled object may be not only the target position, which is the output of the PID controller 5, but also input information to the controlled object such as target torque and target motor current.

Further, fp_ref is calculated by the processing shown in FIG. Specifically, since it is the same as that of the first embodiment, a detailed description thereof will be omitted.

Further, if change is permitted, a desired change parameter (parameter value) of the output value calculator 4 is calculated. Specifically, since it is the same as the first embodiment shown in FIG. 8, a detailed description thereof will be omitted.

<Desired output value calculator (Fig. 24)>
The desired output value calculator 4 calculates a desired profile of the output of the controlled object (for example, the position of the robot 9) based on the control target. Specifically, as shown in FIG. 24, a desired position De_POS is calculated using, for example, a transfer function for the target position Tg_POS, which is the control target. Control targets include, for example, step signals and ramp signals.

Also, b1, which is one of the parameters of the transfer function, is variable, and the value calculated by the parameter changer 6 is preferably used. The parameter b1 is one of the coefficients of the denominator polynomial of the transfer function, and the larger the value of b1, the slower the response of the transfer function.

<Controlled object abnormality determination unit (Fig. 10)>
The controlled object abnormality determination unit 3 detects an abnormality of the controlled object based on the changed parameters calculated by the parameter change unit 6 . Specifically, since it is the same as the first embodiment shown in FIG. 10, the details will not be described.

According to this embodiment, the control device 1 that adjusts the gain value of the PID controller 5 includes the desired output value calculator 4 that calculates a desired output value of the controlled object, and the desired output value (time-series signal etc.) and the output value of the controlled object (such as a time-series signal), a PID controller gain value adjustment unit 2 that adjusts the gain value of the PID controller 5, and an input to the controlled object a parameter changing unit 6 for changing a parameter value of a desired output value calculating unit 4 based on at least one of information, output information from the controlled object, and a gain value of the PID controller 5; and a controlled object abnormality determination unit 3 for determining whether or not the controlled object is normal based on the parameter value of 4. Also, the desired output value calculator 4 is represented by a transfer function. Also, the parameter changing unit 6 changes the time constant of the transfer function. Further, the controlled object abnormality determination unit 3 determines that the controlled object is abnormal when the time constant of the transfer function is equal to or greater than a predetermined value. Also, the control device is a device for controlling the robot 9 .

When at least one of overshoot and undershoot of the measured value and estimated output of the controlled object occurs (when not within a predetermined range), the output value of the desired output value calculation unit 4 is theoretically There is a possibility that the output value (profile) cannot be realized. That is, there is a possibility that the output value (profile) cannot be realized by correcting the gain value of the PID controller 5 . In this case, in order to suppress overshoot and undershoot, it is necessary to correct the desired output value (profile) of the controlled object to a theoretically achievable one. When the desired output value calculator 4 is represented by a transfer function, the larger the value corresponding to the time constant in the denominator polynomial of the transfer function, the slower the responsiveness of the transfer function. Therefore, in order to delay the responsiveness of the transfer function until at least one of the amount of overshoot and the amount of undershoot becomes considerably small, the value corresponding to the time constant in the denominator polynomial of the transfer function is increased.

Further, when the input value to the controlled object is not within the predetermined range, or when the input value to the controlled object reaches a predetermined value, the desired output value of the output value calculation unit 4 is , the output value (profile) may be unrealizable. That is, there is a possibility that the input value to the controlled object such as the manipulated variable becomes an unrealizable output value (profile). In this case, in order to optimize the input value to the controlled object, it is necessary to correct the desired output value (profile) of the controlled object to a realistically realizable one. When the desired output value calculator 4 is represented by a transfer function, the larger the value corresponding to the time constant in the denominator polynomial of the transfer function, the slower the responsiveness of the transfer function. Therefore, the value corresponding to the time constant in the denominator polynomial of the transfer function is increased in order to delay the responsiveness of the transfer function until the gain value is optimized (for example, within a predetermined range).

Further, when the gain value newly calculated in the PID controller gain value adjusting section 2 is not within the predetermined range, or when the newly calculated gain value reaches a predetermined value, the desired output value calculating section 4 may be an output value (profile) that cannot be realized realistically due to the specifications of the control system. That is, there is a possibility that the output value (profile) cannot be realized by correcting the gain value of the PID controller 5 . In this case, in order to optimize the newly calculated gain value, it is necessary to correct the desired output value (profile) of the controlled object so as to be realistically achievable. When the desired output value calculator 4 is represented by a transfer function, the larger the value corresponding to the time constant in the denominator polynomial of the transfer function, the slower the responsiveness of the transfer function. Therefore, the value corresponding to the time constant in the denominator polynomial of the transfer function is increased in order to delay the responsiveness of the transfer function until the gain value is optimized (for example, within a predetermined range).

In the configuration for adjusting the gain value of the PID controller 5 so that the difference between the desired output value (time-series signal, etc.) and the output value of the controlled object (time-series signal, etc.) is small, At least one of the input information to the controlled object, the output information from the controlled object, and the gain value of the PID controller 5 is determined based on the characteristics. Further, based on at least one of the input information to the controlled object, the output information from the controlled object, and the gain value of the PID controller 5, the parameter value of the desired output value calculation unit 4 is updated. The desired parameter value of the output value calculator 4 reflects the characteristics of the controlled object.

Therefore, the characteristics of the controlled object can be detected based on the desired parameter values of the output value calculator 4, and it can be determined whether the characteristics of the controlled object are normal or abnormal by evaluating the parameter values.

As described above, according to the present embodiment, it is possible to automatically adjust the PID gain value so as to obtain desired output characteristics according to changes in the characteristics of the controlled object, and to control whether the controlled object is normal or abnormal. can be detected, the reliability and accuracy of the robot control system can be improved.

[Example 6]
In the present embodiment, a desired output value calculator for calculating a desired output value of the controlled object, and a calculation unit for calculating the desired output value (time-series signal, etc.) and the output value (time-series signal, etc.) of the controlled object. A PID controller gain value adjustment unit that adjusts the gain value of the PID controller so that the difference becomes small, input information to the controlled object, output information from the controlled object, and gain value of the PID controller a parameter changing unit for changing the parameter value of the desired output value calculating unit based on at least one; and determining whether the controlled object is normal based on the parameter value of the desired output value calculating unit. A control device including a controlled object abnormality determination unit that performs the control is shown.

Also, the desired output value calculator is represented by a transfer function.

Also, the parameter changing unit changes the time constant of the transfer function.

Further, the controlled object abnormality determination unit determines that the controlled object is abnormal when the time constant of the transfer function is equal to or greater than a predetermined value.

Further, the control device is a device for controlling a flying object such as a drone.

FIG. 1 shows the overall configuration of the control device 1, which is the same as that of the first embodiment, and will not be described in detail. FIG. 2 shows the system configuration of the control device 1, which is the same as that of the first embodiment, and will not be described in detail.

FIG. 25 is a diagram showing the control device 1 and the drone 10 controlled by the control device 1. As shown in FIG. The PID controller 5 calculates the manipulated variable (for example, the rotational speed of each rotor) for controlling the motion of the drone 10 .

Details of each process will be described below.

<PID controller gain value adjustment unit (Fig. 26)>
The PID controller gain value adjusting section 2 adjusts the gain value of the PID controller 5 . Specifically, it is shown in FIG.

The post-adjustment PID gain provisional value is determined so that the difference between the flight speed FSP profile and the desired flight speed De_FSP profile is minimized. The obtained provisional values of the P-gain value, I-gain value and D-gain value of the PID controller 5 are defined as Kp_new, Ki_new and Kd_new, respectively.

The evaluation function for evaluating the difference between the profile of the position POS and the profile of the desired position De_POS is, for example, the L2 norm that is J2=||FSP-De_FSP|| or the L1 norm that is J1=|FSP-De_FSP| and so on. The PID gain value that minimizes J1 and J2 may be determined by data-driven control such as IFT (Iterative Feedback Tuning) and FRIT (Fictitious Reference Iterative Tuning). return home. There are various methods such as Newton's method, Gauss-Newton's method, etc. for optimization, and there are many references, so they will not be described in detail here.

Note that this optimization process may be performed either offline or online.

<Parameter changing unit (Figs. 27, 28, 7, 8)>
The parameter changing unit 6 determines at least one of whether or not the overshoot amount of the output from the controlled object is within a predetermined range and whether or not the undershoot amount is within a predetermined range. is permitted to change the parameters of the output value calculation unit 4 of . Specifically, the parameter change permission flag fp_ref is calculated by the three determination processes shown in FIGS. The parameters of the output value calculator 4 are calculated. Note that at least one of the three determination processes shown in FIGS. 27, 28, and 7 may be implemented.

For example, the processing shown in FIG. 27 is executed to calculate the parameter change permission flag fp_ref.
- When the following condition a) is satisfied, the parameter change permission flag fp_ref=1 is output. On the other hand, if the condition a) is not satisfied, the parameter change permission flag fp_ref=0 is output.
Condition a)
The overshoot amount of FSP is K_FSP_O1 or more, or
FSP undershoot amount is more than K_FSP_U1

Also, the processing shown in FIG. 28 is executed to calculate the parameter change permission flag fp_ref.
- When the following condition a) is satisfied, the parameter change permission flag fp_ref=1 is output. On the other hand, if the condition a) is not satisfied, the parameter change permission flag fp_ref=0 is output.
Condition a)
Tg_FSP≧K_Tg_FSP_H

Instead of Tg_FSP (target flight speed), which is the output of the PID controller 5, it may be determined whether or not each of the P, I, and D minutes calculated by the PID controller 5 is within a predetermined range. . The input to the controlled object may be not only the target flight speed, which is the output of the PID controller 5, but also input information to the controlled object such as the target rotor rotational speed and the target motor current.

Further, fp_ref is calculated by the processing shown in FIG. Specifically, since it is the same as that of the first embodiment, a detailed description thereof will be omitted.

Further, if change is permitted, a desired change parameter (parameter value) of the output value calculator 4 is calculated. Specifically, since it is the same as the first embodiment shown in FIG. 8, a detailed description thereof will be omitted.

<Desired output value calculator (Fig. 29)>
The desired output value calculator 4 calculates a desired profile of the output of the controlled object (for example, the flight speed of the drone 10) based on the control target. Specifically, as shown in FIG. 29, a desired position De_FSP is calculated for the target flight speed Tg_FSP, which is the control target, using, for example, a transfer function. A control target is, for example, a step signal, a ramp signal, or the like.

Also, b1, which is one of the parameters of the transfer function, is variable, and the value calculated by the parameter changer 6 is preferably used. The parameter b1 is one of the coefficients of the denominator polynomial of the transfer function, and the larger the value of b1, the slower the response of the transfer function.

<Controlled object abnormality determination unit (Fig. 10)>
The controlled object abnormality determination unit 3 detects an abnormality of the controlled object based on the changed parameters calculated by the parameter change unit 6 . Specifically, since it is the same as the first embodiment shown in FIG. 10, the details will not be described.

According to this embodiment, the control device 1 that adjusts the gain value of the PID controller 5 includes the desired output value calculator 4 that calculates a desired output value of the controlled object, and the desired output value (time-series signal etc.) and the output value of the controlled object (such as a time-series signal), a PID controller gain value adjustment unit 2 that adjusts the gain value of the PID controller 5, and an input to the controlled object a parameter changing unit 6 for changing a parameter value of a desired output value calculating unit 4 based on at least one of information, output information from the controlled object, and a gain value of the PID controller 5; and a controlled object abnormality determination unit 3 for determining whether or not the controlled object is normal based on the parameter value of 4. Also, the desired output value calculator 4 is represented by a transfer function. Also, the parameter changing unit 6 changes the time constant of the transfer function. Further, the controlled object abnormality determination unit 3 determines that the controlled object is abnormal when the time constant of the transfer function is equal to or greater than a predetermined value. Also, the control device is a device that controls a flying object such as the drone 10 .

When at least one of overshoot and undershoot of the measured value and estimated output of the controlled object occurs (when not within a predetermined range), the output value of the desired output value calculation unit 4 is theoretically There is a possibility that the output value (profile) cannot be realized. That is, there is a possibility that the output value (profile) cannot be realized by correcting the gain value of the PID controller 5 . In this case, in order to suppress overshoot and undershoot, it is necessary to correct the desired output value (profile) of the controlled object to a theoretically achievable one. When the desired output value calculator 4 is represented by a transfer function, the larger the value corresponding to the time constant in the denominator polynomial of the transfer function, the slower the responsiveness of the transfer function. Therefore, in order to delay the responsiveness of the transfer function until at least one of the amount of overshoot and the amount of undershoot becomes considerably small, the value corresponding to the time constant in the denominator polynomial of the transfer function is increased.

Further, when the input value to the controlled object is not within a predetermined range, or when the input value to the controlled object reaches a predetermined value, the desired output value of the output value calculation unit 4 is , the output value (profile) may be unrealizable. That is, there is a possibility that the input value to the controlled object such as the manipulated variable becomes an unrealizable output value (profile). In this case, in order to optimize the input value to the controlled object, it is necessary to correct the desired output value (profile) of the controlled object so as to be realistically achievable. When the desired output value calculator 4 is represented by a transfer function, the larger the value corresponding to the time constant in the denominator polynomial of the transfer function, the slower the responsiveness of the transfer function. Therefore, the value corresponding to the time constant in the denominator polynomial of the transfer function is increased in order to delay the responsiveness of the transfer function until the gain value is optimized (for example, within a predetermined range).

Further, when the gain value newly calculated in the PID controller gain value adjusting section 2 is not within the predetermined range, or when the newly calculated gain value reaches a predetermined value, the desired output value calculating section 4 may be an output value (profile) that cannot be realized realistically due to the specifications of the control system. That is, there is a possibility that the output value (profile) cannot be realized by correcting the gain value of the PID controller 5 . In this case, in order to optimize the newly calculated gain value, it is necessary to correct the desired output value (profile) of the controlled object so as to be realistically achievable. When the desired output value calculator 4 is represented by a transfer function, the larger the value corresponding to the time constant in the denominator polynomial of the transfer function, the slower the responsiveness of the transfer function. Therefore, the value corresponding to the time constant in the denominator polynomial of the transfer function is increased in order to delay the responsiveness of the transfer function until the gain value is optimized (for example, within a predetermined range).

In the configuration for adjusting the gain value of the PID controller 5 so that the difference between the desired output value (time-series signal, etc.) and the output value of the controlled object (time-series signal, etc.) is small, At least one of the input information to the controlled object, the output information from the controlled object, and the gain value of the PID controller 5 is determined based on the characteristics. Further, based on at least one of the input information to the controlled object, the output information from the controlled object, and the gain value of the PID controller 5, the parameter value of the desired output value calculation unit 4 is updated. The desired parameter value of the output value calculator 4 reflects the characteristics of the controlled object.

Therefore, the characteristics of the controlled object can be detected based on the desired parameter values of the output value calculator 4, and it can be determined whether the characteristics of the controlled object are normal or abnormal by evaluating the parameter values.

As described above, according to the present embodiment, it is possible to automatically adjust the PID gain value so as to obtain desired output characteristics according to changes in the characteristics of the controlled object, and to control whether the controlled object is normal or abnormal. can be detected, so the reliability and accuracy of the drone control system can be improved.

As described above, according to the embodiment of the present invention, the control device 1 that adjusts the gain value of the PID controller 5 is controlled by the desired and a PID controller gain that calculates the gain value of the PID controller 5 so that the difference between the desired output value and the output value of the controlled object becomes small. A parameter value of a desired output value calculation unit 4 is changed based on at least one of value adjustment unit 2, input information to the controlled object, output information from the controlled object, and gain value of PID controller 5. and a controlled object abnormality determination unit 3 for determining whether or not the controlled object is normal based on the parameter value of the desired output value calculation unit 4, so that the desired output value calculation The characteristics of the controlled object can be detected based on the parameter values of the unit 4, and it can be determined whether the characteristics of the controlled object are normal or abnormal by evaluating the parameter values. Therefore, the reliability and accuracy of the plant control system can be improved.

Further, since the desired output value calculator 4 is represented by a transfer function, it is possible to easily calculate the desired output value to be output to the controlled object. Moreover, the desired parameter value of the output value calculator 4 can be easily changed according to the parameter value of the transfer function.

Moreover, since the parameter changer 6 changes the dead time of the transfer function as a desired parameter value of the output value calculator 4, the characteristics of the system can be controlled by the time required for the characteristics of the controlled object to rise.

Further, when the dead time of the transfer function is equal to or greater than a predetermined value, the controlled object abnormality determination unit 3 determines that the controlled object is abnormal. I can judge.

Moreover, since the parameter changer 6 changes the time constant of the transfer function as a desired parameter value of the output value calculator 4, the system characteristics can be controlled by the rise time of the characteristics of the controlled object.

In addition, when the time constant of the transfer function is equal to or greater than a predetermined value, the controlled object abnormality determination unit 3 determines that the controlled object is abnormal. Therefore, the system abnormality can be determined based on the rise time of the characteristics of the controlled object. .

Further, the parameter changing unit 6 changes the order of the transfer function as a desired parameter value of the output value calculating unit 4, so that the system characteristics can be controlled by controlling the complexity of the operation of the controlled object.

In addition, when the order of the transfer function is equal to or greater than a predetermined value, the controlled object abnormality determination unit 3 determines that the controlled object is abnormal. can be determined.

It should be noted that the present invention is not limited to the embodiments described above, but includes various modifications and equivalent configurations within the scope of the appended claims. For example, the above-described embodiments have been described in detail for easy understanding of the present invention, and the present invention is not necessarily limited to those having all the described configurations. Also, part of the configuration of one embodiment may be replaced with the configuration of another embodiment. Moreover, the configuration of another embodiment may be added to the configuration of one embodiment. Further, additions, deletions, and replacements of other configurations may be made for a part of the configuration of each embodiment.

In addition, each configuration, function, processing unit, processing means, etc. described above may be realized by hardware, for example, by designing a part or all of them with an integrated circuit, and the processor realizes each function. It may be realized by software by interpreting and executing a program to execute.

Information such as programs, tables, and files that implement each function can be stored in storage devices such as memories, hard disks, SSDs (Solid State Drives), or recording media such as IC cards, SD cards, and DVDs.

In addition, the control lines and information lines indicate those considered necessary for explanation, and do not necessarily indicate all the control lines and information lines necessary for mounting. In practice, it can be considered that almost all configurations are interconnected.

1 Control device 2 PID controller gain value adjustment unit 3 Control object abnormality determination unit 4 Desired output value calculation unit 5 PID controller 6 Parameter change unit 7 Power plant 8 Self-driving car 9 Robot 10 Drone 11 Storage device 12 of control device CPU of control device
13 ROM of control device
14 RAM of the controller
15 control device data bus 16 control device input circuit 17 control device input/output port 18 control device output circuit

Claims (9)

a computing unit that computes a desired output value of the controlled object;
a gain value adjustment unit that calculates a gain value of the PID controller so that the difference between the desired output value and the output value of the controlled object is small;
determining whether at least one of input information to the controlled object, output information from the controlled object, and gain value of the PID controller is within a predetermined range; a parameter change unit that permits parameter change and, if permitted, changes the parameter value of the calculation unit;
and a determination unit that determines that the controlled object is abnormal when the parameter value of the calculation unit is out of a predetermined range . The control device according to claim 1,
The control device, wherein the calculation unit is represented by a transfer function. In the control device according to claim 2,
The control device, wherein the parameter changing unit changes the dead time of the transfer function as the parameter value of the calculating unit. In the control device according to claim 2,
The control device, wherein the parameter changing unit changes a time constant of the transfer function as the parameter value of the calculating unit. In the control device according to claim 2,
The control device, wherein the parameter changing unit changes the order of the transfer function as the parameter value of the calculating unit. In the control device according to claim 2,
The control device, wherein the determining unit determines that the controlled object is abnormal when the dead time of the transfer function is equal to or greater than a predetermined value. In the control device according to claim 2,
The control device, wherein the determination unit determines that the controlled object is abnormal when the time constant of the transfer function is equal to or greater than a predetermined value. In the control device according to claim 2,
The control device, wherein the determining unit determines that the controlled object is abnormal when the order of the transfer function is equal to or greater than a predetermined value. The control device according to claim 1,
A control device that is at least one of a device for controlling the temperature of a plant, a device for controlling an automatic driving vehicle, a device for controlling a robot, and a device for controlling an aircraft.

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